Multiheme Cytochromes and the Bacterial Nanowires of Shewanella oneidensis MR-1: Regulation, Structure, and Extracellular Electron Transport Mechanisms

Abstract

Dissimilatory metal-reducing bacteria can extract free energy from their environment by performing electron transfer to solid-phase minerals outside the cell. This extracellular electron transport (EET) has important implications in global elemental cycles as well as renewable energy technologies. Among the pathways for EET, bacterial nanowires have received significant attention in the past decade due to their unique ability to mediate long-range electron transport to electron acceptors microns away from the cell surface. Here we report a comprehensive characterization of the composition, structure, and regulatory network that underlies bacterial nanowires from the metal-reducing bacterium Shewanella oneidensis MR-1. Using fluorescent and atomic force techniques, we find that the Shewanella nanowires are extensions of the outer membrane and periplasm that contain multiple multiheme cytochromes. The localization of decaheme cytochromes MtrC and OmcA supports a multistep redox hopping mechanism, allowing long-range electron transport along a membrane network of heme cofactors that line the nanowires. The electron flux resulting from such a mechanism strongly depends on the cytochrome density and topology. Using correlated electron cryo-tomography and in vivo fluorescent microscopy, we are gaining new insight into the localization patterns of cytochromes along nanowires as well as the morphology and the formation mechanism of these structures. Finally, we report our progress on understanding the underlying regulatory network, by testing targeted mutations and analyzing the transcriptome of Shewanella chemostat cultures as they encounter electron acceptor limitation and form nanowires. The transcriptional response includes an increase in the expression of multiheme cytochromes, heme synthesis enzymes, and cytochrome maturation proteins. Our findings on the regulation, ultrastructure and electron transport mechanism help shape a biophysical understanding of these redox-functionalized membrane and vesicular extensions as a microbial strategy for electron transport and energy distribution.

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